Consider following sample code:

class C
    int* x;

void f()
    C* c = static_cast<C*>(malloc(sizeof(C)));
    c->x = nullptr; // <-- here

If I had to live with the uninitialized memory for any reason (of course, if possible, I'd call new C() instead), I still could call the placement constructor. But if I omit this, as above, and initialize every member variable manually, does it result in undefined behaviour? I.e. is circumventing the constructor per se undefined behaviour or is it legal to replace calling it with some equivalent code outside the class?

(Came across this via another question on a completely different matter; asking for curiosity...)

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    This particular code is fine, because C is a POD. As long as C is a POD, it can be initialized that way as well. – Nawaz Jun 5 '16 at 18:09
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    Technically it is no undefined behavior (as long as no constructor or destructor is invoked) : See also std::is_trivial. – user2249683 Jun 5 '16 at 18:18
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    @LightnessRacesinOrbit: Explain further please. – Nawaz Jun 6 '16 at 8:45
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    @Nawaz: There are many ways in which C++ is not compatible with C. The necessity of casting the result of malloc, for example. Assuming that something is true in C++ because it is true in C is patently false. – Lightness Races in Orbit Jun 6 '16 at 9:11
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    You have just pointed out a catastrophic error in the standard documents, going back a long time. The claim that a new expression is necessary to create an object is an obvious contradiction in the std and contradicts common sense. – curiousguy Jun 11 '16 at 5:24

It is legal now, and retroactively since C++98!

Indeed the C++ specification wording till C++20 was defining an object as (e.g. C++17 wording, [intro.object]):

The constructs in a C++ program create, destroy, refer to, access, and manipulate objects. An object is created by a definition (6.1), by a new-expression (, when implicitly changing the active member of a union (12.3), or when a temporary object is created (7.4, 15.2).

The possibility of creating an object using malloc allocation was not mentioned. Making it a de-facto undefined behavior.

It was then viewed as a problem, and this issue was addressed later by https://wg21.link/P0593R6 and accepted as a DR against all C++ versions since C++98 inclusive, then added into the C++20 spec, with the new wording:


  1. The constructs in a C++ program create, destroy, refer to, access, and manipulate objects. An object is created by a definition, by a new-expression, by an operation that implicitly creates objects (see below)...


  1. Further, after implicitly creating objects within a specified region of storage, some operations are described as producing a pointer to a suitable created object. These operations select one of the implicitly-created objects whose address is the address of the start of the region of storage, and produce a pointer value that points to that object, if that value would result in the program having defined behavior. If no such pointer value would give the program defined behavior, the behavior of the program is undefined. If multiple such pointer values would give the program defined behavior, it is unspecified which such pointer value is produced.

The example given in C++20 spec is:

#include <cstdlib>
struct X { int a, b; };
X *make_x() {
   // The call to std​::​malloc implicitly creates an object of type X
   // and its subobjects a and b, and returns a pointer to that X object
   // (or an object that is pointer-interconvertible ([basic.compound]) with it), 
   // in order to give the subsequent class member access operations   
   // defined behavior. 
   X *p = (X*)std::malloc(sizeof(struct X));
   p->a = 1;   
   p->b = 2;
   return p;
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    Hurray, my code suddenly started behaving in a defined way after all these years (: – jwd Jun 23 '20 at 18:55
  • Wow, backported to C++98?!? Mind blown. How common is that? Mind you, something that made probably oodles of extant code UB, chiefly including anything which used malloc()... had to be treated as such, I guess. Between this and P1839R2, things are looking up - eh, @jwd ? ;-) I might not have to rewrite so much of that old code one day! – underscore_d Jun 24 '20 at 9:08
  • Seems fine for my example – if adding a custom constructor (with parameters or default), though, we wouldn't be able to implicitly create an object any more, I assume? So then still UB? – Aconcagua Jun 25 '20 at 6:52
  • @Aconcagua Yes, it is still UB because X would no longer be an implicit-lifetime type (the link explains the rationale). However, you can still interpret p as an array of X and do pointer arithmetic or placement new on it, but not accessing the members. – Meowmere Jan 1 at 1:38

There is no living C object, so pretending that there is one results in undefined behavior.

P0137R1, adopted at the committee's Oulu meeting, makes this clear by defining object as follows ([intro.object]/1):

An object is created by a definition ([basic.def]), by a new-expression ([expr.new]), when implicitly changing the active member of a union ([class.union]), or when a temporary object is created ([conv.rval], [class.temporary]).

reinterpret_cast<C*>(malloc(sizeof(C))) is none of these.

Also see this std-proposals thread, with a very similar example from Richard Smith (with a typo fixed):

struct TrivialThing { int a, b, c; };
TrivialThing *p = reinterpret_cast<TrivialThing*>(malloc(sizeof(TrivialThing))); 
p->a = 0; // UB, no object of type TrivialThing here

The [basic.life]/1 quote applies only when an object is created in the first place. Note that "trivial" or "vacuous" (after the terminology change done by CWG1751) initialization, as that term is used in [basic.life]/1, is a property of an object, not a type, so "there is an object because its initialization is vacuous/trivial" is backwards.

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    C is POD. If so, then I dont see why that should be UB. – Nawaz Jun 5 '16 at 18:12
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    At least that is what en.cppreference.com/w/cpp/concept/PODType says (you can create PODs via malloc). I currently can't find hard evidence in the standard but it allows conversion of T* into U* if alignment req. of U is not stricter than T and if both are standard-layout types. (Where there also isn't any actual U object around which is created via definition, new-expression or by the implementation.) – Pixelchemist Jun 5 '16 at 18:27
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    So does that apply to int too? If not, why not? If yes, can we malloc anything at all? – Baum mit Augen Jun 5 '16 at 18:57
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    Consider also this footnote "39) This section does not impose restrictions on indirection through pointers to memory not allocated by ::operator new. This maintains the ability of many C++ implementations to use binary libraries and components written in other languages. In particular, this applies to C binaries, because indirection through pointers to memory allocated by std::malloc is not restricted." – Ben Voigt Jun 5 '16 at 20:24
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    @hvd A placement new (since that's what's being bypassed here) has two effects: 1. it creates an object; 2. it runs the initialization. Just because #2 has no effect doesn't mean you can bypass #1. – T.C. Jun 6 '16 at 19:40

I think the code is ok, as long as the type has a trivial constructor, as yours. Using the object cast from malloc without calling the placement new is just using the object before calling its constructor. From C++ standard 12.7 [class.dctor]:

For an object with a non-trivial constructor, referring to any non-static member or base class of the object before the constructor begins execution results in undefined behavior.

Since the exception proves the rule, referrint to a non-static member of an object with a trivial constructor before the constructor begins execution is not UB.

Further down in the same paragraphs there is this example:

extern X xobj;
int* p = &xobj.i;
X xobj;

This code is labelled as UB when X is non-trivial, but as not UB when X is trivial.

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    Thanks, that is a good hint - in case of a non-trivial X, it is even stricter than my code. However, in case of a trivial one, it seems weaker to me, as only the address of the member is taken, bot not a value assigned. – Aconcagua Jun 6 '16 at 5:06
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    First, this is different because there's unambiguously an object created by the definition X xobj;, whereas the malloc case is at a minimum substantially more questionable. Second, while referring "to a non-static member of an object with a trivial constructor before the constructor begins execution" does not have UB, in cases where such an object has non-vacuous initialization (e.g., initialization by a trivial copy constructor) [basic.life]/6-7 severely constrains what you can do with it before its lifetime starts: any attempt to access such a member results in UB. – T.C. Jun 6 '16 at 16:02
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    1) You are still operating on the assumption that malloc creates an object, which a) is at least debatable, b) is not the reading of the core working group (as far as I can tell, based on the publicly available discussions on P0137), and c) will likely be unambiguously clarified the other way soon-ish by a revision of that paper. 2) [class.cdtor]/1 does not disallow "referring" to a non-static data member if the object has no non-trivial constructor. But "accessing" (that is, reading or writing) said data member is still UB per [basic.life]/6-7 if its initialization is non-vacuous. – T.C. Jun 6 '16 at 18:12
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    @T.C.: 1a) malloc allocates storage of appropriate size and alignment, so if the type is trivially constructible, it creates an object, AIUI. 1b) Where can I read P0137? I cannot find it anywhere. 2) You say if its initialization is non-vacuous, but I stand that malloc of a trivially constructible type is a vacuously initialized object, so any reading or writing of its members is well defined. – rodrigo Jun 6 '16 at 18:26
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    1b) wg21.link/P0137; Richard Smith's current WIP draft can be found here. That paper went through multiple CWG reviews, starting from when it was N4430, and has consistently maintained that the status quo is "malloc alone is not sufficient to create an object", so I think it's fair to assume that CWG is in agreement with that statement. – T.C. Jun 6 '16 at 19:32

For the most part, circumventing the constructor generally results in undefined behavior.

There are some, arguably, corner cases for plain old data types, but you don't win anything avoiding them in the first place anyway, the constructor is trivial. Is the code as simple as presented?


The lifetime of an object or reference is a runtime property of the object or reference. An object is said to have non-vacuous initialization if it is of a class or aggregate type and it or one of its subobjects is initialized by a constructor other than a trivial default constructor. [ Note: initialization by a trivial copy/move constructor is non-vacuous initialization. — end note ] The lifetime of an object of type T begins when:

  • storage with the proper alignment and size for type T is obtained, and
  • if the object has non-vacuous initialization, its initialization is complete.

The lifetime of an object of type T ends when:

  • if T is a class type with a non-trivial destructor ([class.dtor]), the destructor call starts, or
  • the storage which the object occupies is reused or released.

Aside from code being harder to read and reason about, you will either not win anything, or land up with undefined behavior. Just use the constructor, it is idiomatic C++.

  • 3
    I find it often very useful to avoid the default ctor for std::complex<double>. The standard requires this to be implemented as two doubles and there is no way to avoid them being set to zero if you default-construct the object. However, that is a very much unnecessary write operation if you overwrite the associated memory in the next step anyway; e.g. due to it being the result of a matrix-matrix multiplication or somesuch. – Claudius Jun 5 '16 at 18:27
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    @Claudius: In that case you can use placement new instead of first doing a default initialization and then assigning new values. – Pixelchemist Jun 5 '16 at 18:30
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    @Pixelchemist All these placement-new calls will still eat up runtime, especially since they’d be in the hot inner loop (and in my particular case I’d have to change the BLAS implementation to achieve this, so it’s out of question). – Claudius Jun 5 '16 at 18:34
  • @Claudius Yeah, that's a good point. Those placement news should be optimised away if immediately followed by an assignment, and a quick check suggests that at least GCC is able to do that, but it may not be that easy with all compilers. – user743382 Jun 6 '16 at 19:34
  • @hvd That is a big if. There may well be a big gap between the allocation and the first write and mixing the two will make things often more complicated. The issue is essentially that std::complex<> default ctor is not trivial and quite frankly, I don’t see why it couldn’t just leave the values uninitialised? – Claudius Jun 7 '16 at 19:06

This particular code is fine, because C is a POD. As long as C is a POD, it can be initialized that way as well.

Your code is equivalent to this:

struct C
   int *x;

C* c = (C*)malloc(sizeof(C)); 
c->x = NULL;

Does it not look like familiar? It is all good. There is no problem with this code.

  • 1
    This answer has -4 with no justification in comments... :( should not even be allowed by SO! – curiousguy Jun 10 '16 at 19:39
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    @curiousguy maybe nobody wants to get into a lame argument. Many posters passionately defend their incorrect answers and never admit to being wrong , so a comment is often an invitation to wasting time followed by personal abuse. – M.M Jun 11 '16 at 3:51
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    @M.M Maybe nobody has evidence. – curiousguy Jun 11 '16 at 4:07
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    @M.M And he provided no quote from a std. – curiousguy Jun 11 '16 at 4:52
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    @M.M: Oops. The OP initially had accepted @rodrigo's answer, with which I agree. T.C's answer (which is currently the accepted answer) doesn't make sense to me, because if that is true, then char * buff = malloc(100); strcpy(buff, "hello"); would also be UB, which is nonsense. – Nawaz Jun 11 '16 at 10:19

While you can initialize all explicit members that way, you cannot initialize everything a class may contain:

  1. references cannot be set outside an initializer list

  2. vtable pointers cannot be manipulated by code at all

That is, the moment that you have a single virtual member, or virtual base class, or reference member, there is no way to correctly initialize your object except by calling its constructor.

  • Virtual members, virtual base classes, reference members and const members will definitely not work w/o ctor. – curiousguy Jun 11 '16 at 1:01
  • "Why the downvote?" I don't know, but maybe because you don't really answer the question. – curiousguy Jun 11 '16 at 4:20
  • @curiousguy I have added the virtual base to my list now, thanks. However, I disagree about the const members: You are perfectly allowed to cast away constness to initialize them anyway, even though you really shouldn't do it. – cmaster - reinstate monica Jun 11 '16 at 19:51
  • @curiousguy Concerning answering the question: Yes, I did not directly answer it. I just gave counterexamples that make it clear why it is a really bad idea to try to circumvent constructor calls, and why there is no way for the language to avoid classifying these counterexamples as undefined behavior. Maybe I was not clear enough about my intentions? – cmaster - reinstate monica Jun 11 '16 at 19:56
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    "You are perfectly allowed to cast away constness" says who? – curiousguy Jun 16 '16 at 23:56

I think it shouldn't be UB. You make your pointer point to some raw memory and are treating its data in a particular way, there's nothing bad here.

If the constructor of this class does something (initializes variables, etc), you'll end up with, again, a pointer to raw, uninitialized object, using which without knowing what the (default) constructor was supposed to be doing (and repeating its behavior) will be UB.


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